A Magnetic Shield for Large-Bore, High Field Magnets

## Abstract A 3.0 Tesla, 0.80‐m bore magnet replaced our previous 1.9 Tesla, 0.76‐m magnet. The 3.0 Tesla replacement magnet had a dipole moment of 1.7 with respect to that of the 1.9 Tesla magnet. The pre‐existing cylindrically symmetric passive steel shielding was modified to confine the fringe f

0.4 V, voltage between source and drain -6 V, voltage between source and second gate -5.5 V. On changing the bias voltage on the first gate over the range 0.3 to 1.8 V the amplification coefficient of the fets changed, but this did not affect the level of the flicker noise of the transistors. All re

For EDS-type magnetically levitated trains, magnetic shielding of stray fields produced by superconducting magnets is an important task. We seek the optimal thickness distribution (configuration) of magnetic material, which is the lightest and keeps the magnetic field at tolerable levels in the vehi

## Abstract Strong, extensive magnetic fringe fields are a significant problem with magnetic resonance imaging magnets. This is particularly acute with 4‐T, whole‐body research magnets. To date this problem has been addressed by restricting an extensive zone around the unshielded magnet or by placi

A description is given of pulsed gradient spin echo (PGSE) NMR experiments in which large pulsed magnetic field gradients may be required. The design contraints are discussed and, in particular, the problem of the use of large pulsed magnetic field gradients in conjunction with large polarizing fiel